1. SRE’s Sanjivani College of Engineering,
Kopargaon
BOUNDARY LAYER AND CONCEPTS
Prepared by
Mr. S.S.Kolapkar
Departmentof civilengineering
2. TOPICS COVERED
1.Concept of Boundary Layer
Different Boundary Layer Thicknesses
2.Nominal Thickness
3.Displacement Thickness
4.Momentum Thickness
5.Energy Thickness
6. Concepts of Boundary Layer separation
7. Methods of controlling the boundary layer
3. 1.Concept of Boundary Layer:
It is a small region in the immediate vicinity of the
boundary surface in which velocity of flowing fluid
increases rapidly from zero at the boundary surface to
the velocity of main stream of flowing fluid.
This layer of flowing fluid is known as BL
NOTE:- i) It is due to the high values of viscosity of
flowing fluid in the vicinity of surface.
ii) Due to this effect most of the energy get lost in this
zone due to viscous shear effect.
4.
5. 2.Nominal Thickness(δ):
Nominal thickness of the boundary layer is defined as
the thickness of zone extending from solid boundary
to a point where velocity reaches 99% of the free
stream velocity (U- Refer previous diagram). It is
based on the fact that beyond this boundary, effect of
viscous stresses can be neglected.
The velocity profile merges smoothly and
asymptotically
6. 3.DisplacementThickness(δ*):
Presence of boundary layer introduces a retardation
to the free stream velocity in the neighborhood of the
boundary. This causes a decrease in mass flow rate
due to presence of boundary layer. A “velocity defect”
of (U - u) exists at a certain distance along y axis.
Displacement thickness is the distance (measured
perpendicular to the boundary) with which the
boundary may be imagined to have been shifted such
that the actual flow rate would be the same as that of
an ideal fluid (with slip) flowing around the displaced
boundary.
7.
8. a decrease in mass flow rate due to presence of boundary layer (i.e. due
to viscous force) is
0
.U u b dy I
Where,
b is the width of the surface in the direction perpendicular to the flow
ρ is the density of flowing fluid
U is the initial stream velocity of flowing fluid
The mass flow rate deficiency by displacing the solid boundary by δ* will be
. . .U b II
Therefore in an incompressible flow equating these two equation will get
0
0
. . . .
1 .
U b U u b dy
u
dy
U
9. 4.Momentum Thickness(δ**):
Retardation of flow within boundary layer
causes a reduction in the momentum flux too.
So similar to displacement thickness, the
momentum thickness (δ**) is defined as the
thickness of an imaginary layer in free stream
flow which has momentum equal to the
deficiency of momentum caused to actual mass
flowing inside the boundary layer
10. Mass flowing per second through the elemental strip is
= ρ x area of strip x velocity
. . .b dy u
Therefore mass momentum of above quantity = mass flowing per second x velocity
2
. . .b dy u
Therefore mass momentum of above quantity in the absence of boundary layer is
( . . )u bdy U
Therefore loss of momentum per second is
2
( . . ) . . .
.
u bdy U b dy u
u U u b dy
Therefore total loss of momentum per second is
0
.u U u b dy I
11. But this is also equal to
2
. .b U II
Therefore from equation I and II we have
0
1 .
u u
dy
U
U
12. 5.Energy Thickness(θ):
Energy thickness (θ) is defined as the distance
perpendicular to the boundary by which the
boundary is to be displaced to compensate for
reduction in kinetic energy of fluid caused due
to formation of boundary layer. It is given by
2
2
0
1 .
u u
dy
U
U
14. i) When the pressure increases in the direction of flow (dp/dx>0), the
pressure forces act opposite to the direction of flow and further
increase the retarding effect of the viscous forces.
ii) Subsequently the thickness of the boundary layer increases rapidly in
the direction of flow.
iii) If these forces act over a long stretch the boundary layer gets
separated from the surface and moves into the main stream.
This phenomenon is called separation.
iv) The point of the body at which the boundary layer is on the verge of
separation from the surface is called “point of separation”.
16. v) Figure shows the fluid flows round the surface (the area of flow
decreases) it is accelerated over the left hand section until at point B the
velocity just outside the boundary is maximum and the pressure is
minimum. Thus from A and B the pressure gradient is negative. As long
as dp/dx<0, the entire boundary layer moves forward.
vi) Beyond B(i.e. along the region BCDE), the area of flow increases and
hence velocity of flow decreases; due to decrease of velocity the
pressure increases (in the direction of flow) and hence the pressure
gradient dp/dx is positive i.e. dp/dx>0.
vii) The value of the velocity gradient (du/dy) at the boundary layer is
zero at the point C, this point is known as a separation point (the
boundary layer start separating from the surface because further
retardation of flow near the surface is physically impossible) large
turbulent eddies are formed downstream of the point of separation. The
disturbed region in which the eddies are formed is called turbulent
wake.
17. 7. Methods of controlling the boundary
layer:
i)Streamlining the body shape.
ii)Tripping the boundary layer from laminar to turbulent by
provision of surface roughness.
iii)Sucking the retarded flow.
iv)Injecting the high velocity fluid in the boundary layer
v)Providing the slots near the leading edge.
vi)Guidance of flow in a confined passage.
vii)Providing a rotating cylinder near the leading edge.
viii)Energizing the flow by introducing optimum amount of swirl
in the incoming flow